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Sesame

Sesame () is an annual in the family, cultivated primarily for its small, protein-rich seeds, which yield a nutritious oil and serve as a versatile ingredient in global cuisines. The typically grows 0.5 to 2 meters tall, featuring lance-shaped leaves and tubular, bell-shaped flowers that bloom in , , or white, followed by elongated capsules containing 50 to 100 flat seeds per pod. Native to tropical regions, sesame thrives in hot, drought-tolerant conditions with well-drained soils, requiring 110 to 150 frost-free days for maturation. One of the world's oldest cultivated crops, sesame originated in and , with evidence of domestication dating back over 5,000 years, and it was prized in ancient by 1600 B.C. for its oil. Archaeological findings, including seeds from 2nd-century B.C. sites in , highlight its early spread across trade routes to the Mediterranean and beyond. Today, it ranks as a major oilseed crop, with global production exceeding 6 million metric tons annually, led by countries like , , and , while the cultivates it mainly in and for both domestic use and export. The seeds, available in colors ranging from white and yellow to black and brown, contain 50-60% oil rich in unsaturated fats like oleic and linoleic acids, along with antioxidants such as sesamol and sesamin that confer a long shelf life. Nutritionally, they provide about 25% protein and essential minerals, supporting uses in baking, tahini paste, halva confections, and spice blends like za'atar. Sesame oil, extracted via pressing, is employed in cooking, cosmetics, and traditional medicine for its anti-inflammatory properties, while the defatted meal serves as high-protein livestock feed. Despite its benefits, sesame is a common allergen, prompting labeling requirements in many regions.

Etymology and History

Etymology

The English word "sesame" entered the language in the early 15th century, derived from the Latin sesamum, which in turn borrowed from the Ancient Greek sēsamon (σήσαμον), referring to the seeds or fruit of the plant. This Greek term traces back to Semitic origins, specifically the Akkadian šamaššammu, a compound word meaning "oil plant" formed from šamnu (oil or fat) and šammum (plant), highlighting the crop's early recognition for its oil-producing qualities. In other ancient languages tied to trade routes, sesame bore related names that underscore its widespread cultivation and exchange. The tila denoted sesame seeds, with the root til implying something unctuous or anointing, reflecting the plant's oily properties and its role in Vedic rituals and cuisine. Similarly, the Arabic simsim (سمسم) stems from the same as the Akkadian form, appearing in classical texts and facilitating the term's dissemination through Islamic trade networks across and the Mediterranean. African linguistic variants emerged prominently in the due to the slave trade. The term "benne," used for sesame in Gullah-Geechee communities of the U.S. South, derives from West African languages such as Mende benné or Malinke bĕne, carrying cultural practices of seed use from enslaved Africans to regions like and . The iconic phrase "Open, sesame!" popularized in Western culture originates from Antoine Galland's 18th-century French translation of the tale "Ali Baba and the Forty Thieves," where it renders the iftāḥ yā simsim (open, O sesame), evoking the magical opening of a treasure cave. Etymologically, the expression draws on roots of the word simsim, possibly alluding to the natural bursting of sesame seed pods or ancient associations of the plant with abundance in Mesopotamian lore.

Origins and Domestication

The earliest archaeological evidence for sesame cultivation comes from the , specifically charred sesame seeds recovered from the site of in modern-day , dated to approximately 3500–3050 BCE. These findings indicate that sesame was already an established crop during the mature Harappan phase, with additional seeds identified at nearby sites such as Miri Qalat in Baluchistan, also dated to around 2700–1900 BCE. The Harappan civilization played a pivotal role in early sesame breeding, as evidenced by the selection of plants from wild populations in the surrounding regions of the , marking the transition from foraging to systematic agriculture in this area. Genetic studies further support domestication likely in the , tracing the crop's origins to over 5,500 years ago based on sequencing and structure analyses of sesame accessions, though the exact center of origin remains debated between and . The wild progenitor is identified as Sesamum indicum subsp. malabaricum (synonymous with S. malabaricum), a species native to and southern , which shares close morphological and genetic affinities with cultivated sesame. These studies reveal a domestication bottleneck, where ancient Harappans selected for advantageous traits from local wild stands, leading to reduced in modern cultivars compared to wild relatives. During this transition, key domestication traits emerged through human selection, including larger seed size and increased oil content, which rose from approximately 23–37% in wild species to 45–50% or higher in early cultivated forms. These changes enhanced sesame's value as an oilseed crop, with Harappan farmers likely propagating variants that produced smoother, more uniform seeds suitable for storage and processing, as inferred from comparative analyses of ancient remains and modern germplasm.

Historical Spread and Significance

Sesame cultivation spread from its likely origins in the to by around 2000 BCE through ancient trade networks, where it was integrated as an important oil crop. By 1500 BCE, the plant had reached , evidenced by references in medical texts like the , which listed among medicinal substances. Further dissemination occurred along trade routes to the and , with cultivation spreading to around the 1st millennium CE and to , including during the (c. 126 BCE), facilitating its adaptation in diverse agricultural systems. In ancient economies, sesame played a key role as a source of and food. In , it was pressed for used in cooking, lamps, and religious offerings to deities, underscoring its value in daily and ceremonial life. Assyrian records from document extensive sesame fields managed as off-season crops alongside , highlighting organized cultivation for production that supported trade and sustenance. Sesame reached the in the via the slave , with enslaved Africans introducing seeds to regions like , where they were grown for oil and incorporated into local cuisine. There, the seeds, known as "benne," featured in traditional wafers—a crispy treat combining sesame with and —reflecting culinary influences in Southern U.S. . Throughout history, sesame has held significance in religious rituals, particularly in , where black sesame seeds are offered during to honor ancestors. These offerings, mixed with water or incorporated into rice balls (pinda daan), symbolize purification and sustenance for the departed souls in this annual fortnight of ancestor worship.

Botanical Description

Plant Morphology

Sesame (Sesamum indicum) is an annual belonging to the family, characterized by its erect growth habit and indeterminate flowering pattern. The plant typically reaches a of 0.5 to 2 , though common cultivars often grow to 50–100 cm, with a well-developed system supporting its upright structure. Stems are quadrangular, longitudinally furrowed, and covered in fine hairs, giving them a slightly rough texture; they may be simple or branched depending on environmental conditions. Leaves are arranged oppositely at the base and may become alternate higher up the , exhibiting variable shapes from ovate to lanceolate, measuring 3–20 cm in length and 1–10 cm in width, with serrated margins on lower leaves and entire edges on upper ones; they are dull green and pubescent. The flowers are axillary, solitary or in small clusters of 2–3, borne on short pedicels of 1–5 mm; each is bisexual and tubular to bell-shaped, with a corolla length of 1.5–3.3 cm, typically in shades of white, pale pink, or mauve-purple, often featuring darker vein markings. Pollination is primarily autogamous, enabling self-fertilization without external aid, though cross-pollination by insects such as bees can occur at rates up to 50%, enhancing genetic diversity in some populations. Flowering begins 35–45 days after planting and continues progressively from the base to the apex, with each flower lasting only a day before wilting. The fruit is an oblong capsule, 1.5–3.5 cm long and 6–7 mm wide, deeply grooved (4-sulcate) and dehiscent, splitting longitudinally into 4 valves at maturity to release the seeds; some varieties exhibit 4–6 compartments internally. Each capsule contains 50–100 flat, ovate seeds arranged in 4–8 rows, with individual seeds measuring 2–4 mm in diameter, pointed at one end, and varying in color from white and yellow to brown or black; the testa is smooth or slightly veined. These seeds are notably oil-rich, comprising 40–60% oil by weight, which contributes to the plant's economic value. The of sesame spans 90–150 days from to , encompassing (5–7 days under warm conditions), vegetative growth (3–4 weeks), flowering (starting around 40–50 days), and capsule maturation, which occurs indeterminately over several weeks; the is day-length sensitive, with 10–12 hour days promoting optimal development. At maturity, leaves and stems turn yellow, and capsules ripen from bottom to top, dehiscing explosively when dry to disperse seeds. Varietal differences may influence height and seed color slightly, but the core morphology remains consistent across most cultivated forms.

Varieties and Genetics

Sesame varieties are primarily distinguished by seed color, which influences their content, levels, and characteristics. White sesame seeds are favored for their high content, typically ranging from 45% to 55%, making them ideal for . In contrast, black sesame seeds are richer in , particularly like sesamin and sesamolin, which contribute to higher total content compared to white varieties. Red and brown sesame seeds often feature thicker, intact that impart a more earthy flavor and provide additional fiber, though they generally have slightly lower yields than white types. A key genetic trait in sesame cultivation is capsule dehiscence, or shattering, where mature seed pods naturally split open, leading to seed loss during harvest. Traditional shattering varieties require manual harvesting to minimize losses, while modern non-shattering types, developed through selective breeding, retain seeds in the pod for easier mechanical harvesting and reduced yield loss of up to 50%. The genus Sesamum encompasses approximately 36 species, primarily distributed in Africa and Asia, with Sesamum indicum as the sole cultivated species. Genetic diversity within S. indicum and its wild relatives has been harnessed through hybridization to enhance drought tolerance and yield, leveraging traits like deep root systems from wild species for improved water-use efficiency under stress conditions. Breeding efforts have focused on developing high-yielding, non-GMO varieties with enhanced disease resistance and shatter resistance. In , conventional has produced varieties like those from the ICAR , achieving yields of 800-1000 kg/ha under rainfed conditions through selection for uniformity and to pests like disease. Recent advancements include genome-wide association studies identifying QTLs for oil content and composition (as of 2025), and new hybrids such as Tilhan Tec-SUNH-2, released in 2024, with potential yields up to 1.57 t/ha. Regionally, Sudanese white sesame varieties such as Setit-2 exhibit high productivity, with yields up to 1.1 tonnes/ in semi-arid conditions, emphasizing white seeds for oil production. In , black "Til" sesame is prized for uses, such as in traditional sweets like ladoos, due to its robust flavor and nutritional profile from the unhulled seeds.

Agricultural Practices

Cultivation Methods

Sesame thrives in tropical and subtropical climates with average temperatures ranging from 20°C to 30°C (68°F to 86°F), requiring 500–700 mm (20–28 inches) of well-distributed rainfall during the , though it exhibits high once established. The crop demands well-drained sandy or medium-textured soils with a of 5.5–8.0 to prevent waterlogging and support optimal root development, as it cannot tolerate high or standing water. Sowing is typically done by direct seeding at rates of 4–6 kg per to achieve adequate , with row spacing of 30–45 cm to facilitate operations and , particularly in irrigated dry areas where supplemental water ensures seed- contact for 3–5 days post-planting. Seeds are planted 1–2 cm deep when temperatures reach at least 20°C (68°F), ideally one month after the last , to promote uniform . Effective crop management involves timely through shallow at 15–20 and 30–35 days after sowing or pre-emergence herbicides like to maintain a weed-free , as sesame is a poor competitor in early growth stages. and resistance is enhanced by selecting varieties tolerant to , a infection spread by leafhoppers, with management including rogueing infected plants and applying insecticides such as or neem-based sprays. with cereals like or is recommended every two years to reduce soil depletion, populations, and buildup of such as . Harvesting occurs at approximately 50% capsule maturity, around 90–110 days after sowing when lower capsules turn lemon yellow and leaves begin to yellow, to capture peak seed quality while minimizing losses. Traditional shattering varieties can incur up to 50% seed loss if delayed, so mechanical harvesting with low cylinder speeds (450–500 rpm) or hand methods are used, prioritizing shatter-resistant varieties to reduce spillage during drydown.

Processing Techniques

Sesame seeds undergo several post-harvest processing steps to prepare them for oil extraction, paste , and other uses. Initial begins with the harvested seeds to a content of approximately 6%, which prevents spoilage and facilitates handling. This is typically achieved through natural field or windrowing, ensuring the seeds are below 6% before storage or further processing. follows to remove such as , dirt, and foreign particles, often using equipment to separate lighter impurities from the denser seeds. Grading then sorts the cleaned seeds by size and color, with color sorters discarding discolored or immature seeds; white or light-colored varieties command higher value due to their aesthetic appeal in food applications. Oil extraction from sesame seeds primarily employs mechanical pressing or solvent methods to recover the seed's oil content, which ranges from 40% to 60% depending on the technique. Mechanical pressing, often using expellers, yields 45–50% oil and is preferred for producing high-quality, aromatic oils, particularly when seeds are pre-heated to around 50°C for optimal flow. Cold-pressing at lower temperatures preserves for oils, while hot-pressing suits industrial applications. Solvent extraction, typically using n-hexane, achieves higher recoveries of 55–60% by dissolving residual oil from the pressed cake, though it requires to remove the . Dehulling precedes extraction for paste production, involving soaking seeds in followed by mechanical or to separate the , enhancing the smoothness of products like . Seed preparation for flavor-intensive products such as tahini and halva often includes roasting to develop nutty aromas through Maillard reactions. Roasting occurs at temperatures of 120–150°C for 10–60 minutes, depending on the desired intensity, with lower temperatures yielding lighter flavors suitable for tahini. Hulling for dehulled seeds uses alkali solutions or mechanical methods like wet abrasion to remove the outer coat, improving digestibility and texture in pastes. Processing generates byproducts like sesame meal or cake, which constitutes the defatted residue after oil extraction and contains 34–50% protein, making it a valuable component for animal feed. Approximately 70% of global sesame production is directed toward oil and meal processing, with the meal serving as a protein-rich feed supplement comparable to soybean meal in livestock diets.

Global Production and Trade

Global sesame production reached approximately 6.8 million tonnes in , with estimates indicating stability around this level as of 2025. leads as the top producer, accounting for about 1.37 million tonnes or 20% of the global total as of 2023, followed by at 0.80 million tonnes, at 0.74 million tonnes, and at 0.46 million tonnes. These figures reflect sesame's status as a major oilseed crop, with contributing over 57% of worldwide output since 2012, underscoring the continent's dominance in volume despite varying regional challenges. Average yields for sesame range from 300 to 500 per globally, influenced by factors such as , rainfall variability, and management practices that can limit output in rainfed systems. In , yields often fall at the lower end of this spectrum due to reliance on traditional farming methods, yet the region's vast sustains its leading production share. International trade in sesame seeds involves annual exports of around 2.5 million tonnes, with major exporters including and , which together supply a significant portion of the global market. Key importers such as , , and drive demand, primarily for food and oil processing, with sourcing heavily from nations like and . In 2024, the average export price stood at $1,772 per tonne, while import prices averaged $1,828 per tonne, though early 2025 trends show a downward shift due to oversupply from . The sesame market is valued at $13.8 billion in , with a projected (CAGR) of 5.8% through 2030, fueled by rising demand in health-focused products and applications.

Environmental Impact

Sesame cultivation is characterized by relatively low demands, with seasonal requirements typically ranging from 390 to 575 mm for non-stressed production, making it a drought-tolerant well-suited to semi-arid regions. This is substantially lower than water-intensive crops like , which often needs 700–1,300 mm per season, allowing sesame to reduce overall needs in systems and conserve resources. Efficient techniques can further save 900–1,200 m³/ha (equivalent to 90–120 mm) compared to conventional methods, promoting in water-scarce areas. Regarding soil health and fertilizer use, sesame exhibits potential for when paired with s such as mycorrhizal fungi or bacteria like , which enhance nutrient uptake without heavy reliance on synthetic inputs. However, high application rates of chemical fertilizers like NPK can increase (GHG) emissions by 20–30% relative to scenarios, primarily through (N₂O) and (NH₃) releases, exacerbating climate impacts. practices heighten risks due to the crop's shallow root system and lack of ground cover, potentially leading to nutrient depletion and in vulnerable regions. Life cycle assessments of sesame production reveal moderate energy inputs, averaging 14.48 /kg of seed, encompassing farming, harvesting, and initial processing stages. Modern systems incorporating efficient and biofertilizers can reduce overall environmental impacts by up to 15–30% compared to traditional methods, primarily by lowering and while maintaining yields. In terms of broader , sesame plays a valuable role in crop rotations, enhancing through or alternation with and cereals, which helps suppress pests and improve . Its potential for bio-pesticides, such as applications at 4 kg/ha or extracts from sesame residues, offers low-toxicity alternatives to synthetics, minimizing harm to beneficial organisms like pollinators and microbes. Nonetheless, poses significant threats, with projections indicating erratic rainfall could reduce sesame yields by 10–20% in rain-fed areas by 2030, particularly in regions like and where variability disrupts flowering and seed set. strategies, including drought-resistant varieties and diversified farming, are essential to bolster resilience.

Nutritional Profile and Health

Chemical Composition

Sesame seeds are a nutrient-dense , characterized by a high content and balanced macronutrient profile. Per 100 g of , whole dried seeds, they provide 573 kcal, with fats comprising the at 49.7 g total , of which approximately 82% is unsaturated (18.8 g monounsaturated, primarily , and 21.8 g polyunsaturated, mainly ). Protein accounts for 17.7 g, while carbohydrates total 23.5 g, including 11.8 g of . The seeds are also rich in minerals, notably calcium at 975 mg, iron at 14.6 mg, and magnesium at 351 mg, contributing to their role as a valuable dietary component.
NutrientAmount per 100 g
573 kcal
Total 49.7 g (82% unsaturated)
Protein17.7 g
Total carbohydrates23.5 g
11.8 g
Calcium975 mg
Iron14.6 mg
Magnesium351 mg
Beyond macronutrients and minerals, sesame contain significant levels of bioactive compounds, particularly , which are oil-soluble unique to the . Sesamin is the predominant lignan, with contents ranging from 0.05 to 1.1 mg/g (0.005–0.11%), while sesamolin ranges from 0 to 1 mg/g (0–0.1%), varying by and growing conditions. Other include tocopherols, primarily γ-tocopherol, at 20–50 mg/100 g, and phytosterols at 400–413 mg/100 g, which support oxidative stability. The lipid fraction constitutes 42–55% of the weight, dominated by unsaturated fatty acids, and induces the formation of sesamol from sesamolin degradation, enhancing antioxidant properties. Varietal differences influence the bioactive profile, with black sesame seeds exhibiting higher anthocyanin content (10–35 mg/100 g) compared to white varieties, attributed to pigments in the intact hull that confer additional antioxidant capacity.

Health Benefits

Sesame consumption has been associated with several cardiovascular benefits, primarily through improvements in lipid profiles and blood pressure regulation. A systematic review and meta-analysis of randomized controlled trials found that sesamin supplementation significantly reduced total cholesterol by 10.9 mg/dL and low-density lipoprotein cholesterol by 8.4 mg/dL, with greater effects observed in individuals with unhealthy baseline levels or after at least 42 days of intervention at doses up to 200 mg/day. Another GRADE-assessed meta-analysis of 13 trials involving 521 participants demonstrated that sesame supplementation (0.06–50 g/day for 4–12 weeks) lowered total cholesterol, particularly at doses ≤10 g/day, in populations with chronic conditions like diabetes. Additionally, sesamin reduced systolic blood pressure by 3.7 mmHg, supporting its role in mitigating hypertension risk. In , sesame products exhibit promising effects on glycemic control and reduction. The same 2025 meta-analysis reported a significant decrease in HbA1c (standardized mean difference -0.67), alongside marginal reductions in fasting blood sugar, attributed to bioactive lignans like sesamol that enhance and defenses. A review of recent trials highlighted sesame's ability to lower HbA1c by approximately 1%, equating to a 15% relative improvement in patients, through sesamol's modulation of glucose metabolism and reduction of . These benefits were observed across forms like seeds, oil, and capsules at doses of 200–60,000 mg/day over 6–12 weeks. Sesame's lignans, particularly sesamin, contribute to and effects that may reduce risk. Sesamin inhibits pro-inflammatory cytokines such as IL-6 and TNF-α by suppressing pathways and reducing COX-2 expression, as shown in cellular and animal models of . A 2023 review linked these actions to decreased endothelial and monocyte adhesion, lowering the progression of atherosclerotic plaques. Furthermore, sesame supplementation significantly reduced IL-6 levels (standardized mean difference -0.74) in human trials, enhancing overall capacity. Beyond these, sesame supports and liver protection. Daily supplementation (0.25–0.5 mL/kg) in ovariectomized rats increased density and trabecular area while balancing and activity through elevated and aromatase levels, suggesting potential for preventing postmenopausal . Its high calcium content, combined with lignans, aids calcium absorption and formation. For liver health, sesame lignans like sesamin activate PPARα and Nrf2 pathways, promoting oxidation, reducing , and mitigating in hepatic cells. A 2025 review noted metabolic support with 30 g/day intake, improving and protecting against .

Adverse Effects and Allergies

Sesame seeds are calorie-dense, providing 573 kcal per 100 g, which may contribute to when consumed in excess without balancing overall caloric intake. Additionally, sesame contains oxalates at levels of 200–400 mg per 100 g, potentially increasing the risk of kidney stone formation in susceptible individuals who consume large amounts. affects approximately 0.23% of the population, equating to roughly 1 million individuals as of 2025. In 2023, the Food and Drug Administration designated sesame as the ninth major allergen under the FASTER Act, mandating its declaration on packaged food labels. This IgE-mediated reaction can manifest as , swelling, gastrointestinal distress, respiratory issues, or severe . A 2025 study reported global sensitization rates to sesame ranging from 0.1% to 0.9%, with co-allergies to nuts occurring in about 54% of cases. Management of sesame allergy primarily involves strict avoidance of sesame-containing products, including seeds, oils, and derivatives like . Individuals diagnosed with should carry epinephrine auto-injectors for immediate use in case of accidental exposure leading to . Regarding , a 2025 pediatric indicated that sesame allergy persists in approximately 50% of affected children into school age, highlighting the need for ongoing monitoring.

Contamination and Safety

Sesame seeds are susceptible to contamination by mycotoxins, particularly aflatoxins produced by fungi during improper storage or handling. Studies have detected levels in sesame seeds ranging from trace amounts to as high as 5.557 ng/g (ppb), with mean concentrations often below 2 ppb in imported samples. , such as absorbed from contaminated soil, have been found in sesame seeds at concentrations typically between 0.1 and 0.5 mg/kg, though levels can vary by region and exceed permissible limits in some cases. Pesticide residues, including and fenvalerate, are also common contaminants, often resulting from post-harvest or agricultural applications, with detections reported in multiple global consignments. Aflatoxins pose significant health risks, classified as Group 1 carcinogens by the International Agency for Research on Cancer, primarily causing liver damage and increasing the incidence of upon chronic exposure. Acute aflatoxin toxicity can lead to hepatic , while long-term ingestion heightens risk, particularly in regions with high consumption of contaminated oilseeds. Economically, incidents trigger recalls that cost the global $10–50 million annually, including direct expenses for product withdrawal and indirect losses from trade disruptions, as seen in multiple sesame-related alerts. Regulatory frameworks address these risks through strict limits and monitoring. The enforces a maximum of 4 ppb for total aflatoxins in oilseeds like sesame, with violations leading to import rejections. Recent 2024 studies on sesame indicate that relative exceeding 12% can substantially elevate growth and production, with infection rates increasing by up to 30% compared to drier conditions. strategies focus on post-harvest practices to minimize . Proper of sesame seeds to below 8% content prevents fungal proliferation during , while gamma at doses of 5–10 kGy effectively reduces levels without compromising seed quality. Emerging 2025 guidelines from bodies like the FDA under FSMA emphasize comprehensive testing, including routine screening for contaminants at every stage from to , to ensure and .

Uses and Cultural Importance

Culinary Applications

Sesame seeds are widely used in culinary preparations around the world, often toasted to enhance their nutty flavor and crunchy texture. In Western , they serve as a popular topping for bagels, where they are sprinkled on the boiled dough before baking to add a subtle sesame essence and visual appeal. In , toasted sesame seeds are ground with salt to create , a versatile condiment sprinkled over rice, , or vegetables for added and seasoning. A key derivative is , a smooth paste made from ground sesame seeds, which originated in the and accounts for a significant portion of global sesame consumption in that form, with the and holding approximately 63% of the tahini market share. is essential in dishes like and baba ganoush, providing creaminess and richness. Globally, around 65% of sesame production is processed into oil for food applications, while the remainder supports direct seed uses in confections and seasonings. Sesame oil, extracted from the seeds, is prized for its aromatic profile and is commonly used in Asian stir-fries to infuse vegetables and meats with its distinctive nutty taste at the end of cooking. In Indian cuisine, it flavors pickles and tempering spices, leveraging its bold flavor. Refined sesame oil has a high smoke point of 210°C, making it suitable for high-heat cooking methods like frying. Sweet confections highlight sesame's versatility, such as , a dense tahini-based paste sweetened with or honey, popular in and as a traditional . In India, is a brittle-like sweet made by binding roasted sesame seeds with , enjoyed as a snack during festivals. Chinese sesame brittle combines toasted seeds with caramelized and often , creating a crunchy treat. Regional variations further diversify sesame's role; in , perilla oil is often blended with for dressings and marinades, imparting an earthy, minty depth to salads and noodles. In , flatbread incorporates black sesame seeds into the dough for subtle nuttiness and texture, typically enjoyed during celebrations.

Industrial Applications

Sesame oil serves as a key ingredient in various sectors due to its emollient properties, , and semi-drying characteristics. In , it functions as an effective emollient and , often incorporated at concentrations of 3–10% in formulations such as facial lotions, moisturizers, and serums to enhance nourishment and without causing . Low-grade sesame oil is also utilized in soaps and lubricants as a , leveraging its content to extend and improve product consistency. In the manufacturing of paints and inks, sesame oil acts as a semi-drying agent, forming a polymeric film upon exposure to air through oxidation of its unsaturated fatty acids, which contributes to the durability and adhesion of coatings. The seed meal byproduct, obtained after oil extraction, is a valuable protein source for , typically containing 40–50% crude protein on a basis, along with essential like , making it suitable for and diets. also shows promise as a feedstock, with potential yields of approximately 585–696 liters per depending on and oil content. Beyond these applications, sesame contributes to perfumes through its aromatic compounds, such as sesamol and furfurylthiol derivatives, which impart nutty, earthy notes in fragrance formulations. In pest control, sesame oil and its extracts serve as natural insecticides and repellents, suffocating by blocking their breathing structures or acting synergistically with other agents. The global non-food market for sesame products, encompassing these industrial uses, accounts for a notable portion of overall production, driven by demand in , pharmaceuticals, and biofuels. Emerging applications include bio-pesticides derived from sesame lignans like sesamin and sesamolin, which enhance efficacy and exhibit activity against pests, offering alternatives to synthetic chemicals. Recent studies have also explored in sustainable inks for additive , such as , where it serves as a biobased to reduce reliance on petroleum-derived materials and lower environmental impact compared to traditional formulations.

Cultural and Symbolic Roles

Sesame holds profound cultural and symbolic significance across various traditions, often embodying themes of prosperity, purity, and eternal life. In , the iconic phrase "" appears in the tale of Ali Baba and the Forty Thieves from , where it magically unlocks a hidden cave brimming with treasures, symbolizing sudden access to wealth and abundance. This narrative, rooted in Middle Eastern folklore, has permeated global culture, evoking ideas of hidden opportunities and fortune. Similarly, in ancient Jewish texts, is referenced as a pure substance suitable for use, such as kindling lights in the , highlighting its role in spiritual purity and consecration where was scarce. In , sesame seeds, known as tila, symbolize immortality and are integral to ancestral rites, particularly during when black sesame is offered to departed souls to aid their journey and cleanse sins, as blessed by , the god of death, in Vedic lore. This practice underscores sesame's association with eternal life and purification in funeral and shraddha ceremonies. In , sesame, especially black varieties, is revered as a tonic for longevity, nourishing the liver and kidneys while combating age-related decline through its rich lignans and antioxidants, as documented in classical texts like the Compendium of Materia Medica. Sesame features prominently in seasonal festivals, reinforcing its lucky and healthful connotations. During Japan's Setsubun, participants throw roasted soybeans to expel evil spirits and invite good fortune, marking the arrival of spring. In Korea's Dano festival, songpyeon rice cakes stuffed with sesame seeds are prepared, believed to promote health and vitality while warding off misfortune through their nourishing properties. In modern culture, sesame has surged as a superfood in wellness trends, prized for its nutrient density including healthy fats and minerals that support overall vitality. Black sesame, in particular, features in beauty rituals for hair and skin, with studies affirming its role in enhancing pigmentation, reducing oxidative stress to delay graying, and improving elasticity via collagen support.